Accuracy of 3D real-time MRI temperature mapping in gel phantoms during microwave heating.

IF 3.7 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Olaf Dietrich, Sergio Lentini, Osman Öcal, Pierre Bour, Thibaut L Faller, Valéry Ozenne, Jens Ricke, Max Seidensticker
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引用次数: 0

Abstract

Background: Interventional magnetic resonance imaging (MRI) can provide a comprehensive setting for microwave ablation of tumors with real-time monitoring of the energy delivery using MRI-based temperature mapping. The purpose of this study was to quantify the accuracy of three-dimensional (3D) real-time MRI temperature mapping during microwave heating in vitro by comparing MRI thermometry data to reference data measured by fiber-optical thermometry.

Methods: Nine phantom experiments were evaluated in agar-based gel phantoms using an in-room MR-conditional microwave system and MRI thermometry. MRI measurements were performed for 700 s (25 slices; temporal resolution 2 s). The temperature was monitored with two fiber-optical temperature sensors approximately 5 mm and 10 mm distant from the microwave antenna. Temperature curves of the sensors were compared to MRI temperature data of single-voxel regions of interest (ROIs) at the sensor tips; the accuracy of MRI thermometry was assessed as the root-mean-squared (RMS)-averaged temperature difference. Eighteen neighboring voxels around the original ROI were also evaluated and the voxel with the smallest temperature difference was additionally selected for further evaluation.

Results: The maximum temperature changes measured by the fiber-optical sensors ranged from 7.3 K to 50.7 K. The median RMS-averaged temperature differences in the originally selected voxels ranged from 1.4 K to 3.4 K. When evaluating the minimum-difference voxel from the neighborhood, the temperature differences ranged from 0.5 K to 0.9 K. The microwave antenna and the MRI-conditional in-room microwave generator did not induce relevant radiofrequency artifacts.

Conclusion: Accurate 3D real-time MRI temperature mapping during microwave heating with very low RMS-averaged temperature errors below 1 K is feasible in gel phantoms.

Relevance statement: Accurate MRI-based volumetric real-time monitoring of temperature distribution and thermal dose is highly relevant in clinical MRI-based interventions and can be expected to improve local tumor control, as well as procedural safety by extending the limits of thermal (e.g., microwave) ablation of tumors in the liver and in other organs.

Key points: Interventional MRI can provide a comprehensive setting for the microwave ablation of tumors. MRI can monitor the microwave ablation using real-time MRI-based temperature mapping. 3D real-time MRI temperature mapping during microwave heating is feasible. Measured temperature errors were below 1 °C in gel phantoms. The active in-room microwave generator did not induce any relevant radiofrequency artifacts.

Abstract Image

微波加热期间凝胶模型中三维实时磁共振成像温度绘图的准确性。
背景:介入性磁共振成像(MRI)可为肿瘤的微波消融提供一个全面的环境,利用基于磁共振成像的温度测绘对能量输送进行实时监测。本研究的目的是通过比较核磁共振测温数据和光纤测温测量的参考数据,量化微波体外加热过程中三维(3D)实时核磁共振测温的准确性:方法:使用室内磁共振条件微波系统和磁共振测温仪,在琼脂凝胶模型中进行了九次模型实验评估。核磁共振成像测量持续了 700 秒(25 个切片;时间分辨率为 2 秒)。温度由两个光纤温度传感器监测,分别距离微波天线约 5 毫米和 10 毫米。传感器的温度曲线与传感器顶端单体素感兴趣区(ROI)的 MRI 温度数据进行了比较;MRI 测温的准确性根据均方根(RMS)平均温差进行评估。还对原始 ROI 周围的 18 个相邻体素进行了评估,并选择温差最小的体素进行进一步评估:微波天线和磁共振成像条件下的室内微波发生器没有引起相关的射频伪影:结论:在凝胶模型中,微波加热过程中精确的三维实时磁共振成像温度绘图是可行的,且均方根温度误差非常低,低于 1 K:基于磁共振成像对温度分布和热剂量进行精确的容积实时监测与基于磁共振成像的临床介入治疗高度相关,有望通过扩大肝脏和其他器官肿瘤热(如微波)消融的范围来改善局部肿瘤控制和手术安全性:要点:介入磁共振成像可为肿瘤的微波消融提供全面的环境。磁共振成像可利用基于磁共振成像的实时温度图监测微波消融。在微波加热过程中进行三维实时磁共振成像温度测绘是可行的。在凝胶模型中测得的温度误差低于1 °C。室内有源微波发生器没有诱发任何相关的射频伪影。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
European Radiology Experimental
European Radiology Experimental Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
6.70
自引率
2.60%
发文量
56
审稿时长
18 weeks
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